Abstract

Residential smart water meters (SWMs) collect real-time water consumption data, enabling automated billing and peak period forecasting. The presence of unsafe events is typically detected via deviations from the benign profile of water usage. However, profiling the benign behavior is non-trivial for large-scale SWM networks because once deployed, the collected data already contain those events, biasing the benign profile. To address this challenge, we propose a real-time data-driven unsafe event detection framework for city-scale SWM networks that automatically learns the profile of benign behavior of water usage. Specifically, we first propose an optimal clustering of SWMs based on the recognition of residential similarity water usage to divide the SWM network infrastructure into clusters. Then we propose a mathematical invariant based on the absolute difference between two generalized means - one with positive and the other with negative order. Next, we propose a robust threshold learning approach utilizing a modified Hampel loss function that learns the robust detection thresholds even in the presence of unsafe events. Finally, we validated our proposed framework using a dataset of 1,099 SWMs over 2.5 years. Results show that our model detects unsafe events in the test set, even while learning from the training data with unlabeled unsafe events.

Department(s)

Computer Science

Keywords and Phrases

Anomaly Detection; Resilient Machine Learning; Smart Living CPS; Smart Water Distribution

Document Type

Article - Conference proceedings

Document Version

Citation

File Type

text

Language(s)

English

Rights

© 2024 Institute of Electrical and Electronics Engineers, All rights reserved.

Publication Date

01 Jan 2024

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